KR100458678B1 - Gain-providing optical power equalizer - Google Patents

Abstract

A gain providing optical power planarizer capable of realizing optical channel output planarization or gain planarization while amplifying signal light is disclosed. The main feature of the optical power flattener of the present invention is to implement optical power flattening by applying different optical gains for each optical channel, as opposed to the prior art in which optical power flattening is implemented by giving different attenuation for each optical channel. According to the present invention, the output of the optical channel can be smoothed and controlled as desired without deteriorating the signal-to-noise ratio.

Description

Gain-Providing Optical Power Equalizers {Gain-providing optical power equalizer}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical power flattener, and more particularly, to a gain providing optical power flattener capable of realizing optical channel output or gain flattening while amplifying signal light.

In general, optical amplifiers widely used in optical communication systems have different gains for different channels (wavelengths). As such, a problem may occur if one channel has a small gain characteristic or a large gain characteristic compared to the other channel. The reason is that if the signal is attenuated or repeatedly re-amplified in an optical amplification system, different gain differences between channels accumulate and become more severe, which can eventually damage the system. Thus, there is a need for gain flattening to have the same gain for different channels (wavelengths).

In the past, a fixed method of modulating the composition of the gain medium constituting the optical amplifier or using a gain flattening filter has been used for the flattening of the gain. However, when the surrounding environment of the optical amplifiers changes, the gain characteristics of the optical amplifiers also vary accordingly. The above-described fixed method has a problem in that it is difficult to actively cope with the change.

Accordingly, a dynamic gain equalizer for varyingly flattening the output of the optical channel is currently proposed. The optical gain flattener includes a splitter for separating the split light source for each wavelength, an attenuator array for attenuating the separated optical power for each channel, and an optical combiner for adding the signal channels flattened by the attenuator. In such a structure, a technique of placing a reflector at the center of the symmetry using the symmetry of the optical combiner and the optical splitter, or inducing optical attenuation by inducing a change in the optical phase difference is a modification of the dynamic light gain flattener described above. In principle, they are identical to each other and are all based on light attenuation. Since the optical gain flattener is based on the optical attenuation, it may be called a lossy optical gain flattener, which can be implemented in various ways. That is, according to the configuration of the optical combiner and the optical splitter using a bulk grating, an arrayed waveguide grating (AWG) or a dielectric filter, and attenuation method using a phase interference or attenuator array or the like. It is possible to implement in various ways. However, since the attenuation of signal light generally causes a deterioration of a signal to noise ratio (SNR) in a communication system, the optical channel output planarization or gain planarization is required from a system design standpoint in the state where the signal light is not attenuated. .

Accordingly, an object of the present invention is to provide an optical power flattener of a gain providing method that can realize flattening of power for each optical channel while amplifying signal light.

Another technical problem of the present invention is to provide a gain-providing optical power planarizer that can realize power flattening for each optical channel without using an array of expensive amplifiers currently commercially available, such as an optical fiber amplifier.

1 is a schematic diagram of an optical waveguide amplifier to which an upper pumping method is applied;

2 is a schematic structural diagram of an optical power flattener according to a first embodiment of the present invention; And

3 is a schematic configuration diagram of an optical power flattener according to a second embodiment of the present invention.

According to an aspect of the present invention, there is provided an optical power flattener of a gain providing method, comprising: an optical power flattener for flattening a power of a signal light output for each optical channel when it is not flat; A splitter for separating signal light having uneven power for each optical channel for each optical channel; A plurality of optical paths configured to pass signal light separated for each optical channel by the splitter; An optical waveguide made of a silica-based material doped with a rare earth element and an upper pump light source for irradiating light from each of the vertical upper portions of the optical waveguide, and provided in each of the optical paths to give different gains for each channel, thereby providing the channel of the signal light. An optical waveguide amplifier array for flattening star power; And an optical combiner for adding signal signals for each optical channel flattened by the optical amplifier array. Characterized in having a.

At least one of the splitter, the combiner, and the optical waveguide amplifier array may be made in a PLC form.

The optical power flattener according to the first aspect may include: a power measurer for measuring the power flattened by the optical waveguide amplifier array for each channel; And a controller for adjusting amplification intensity of each channel of the optical waveguide amplifier array when the planarization result of the power measurement of the power meter does not meet a predetermined criterion. It may be further provided.

According to another aspect of the present invention, there is provided an optical power flattener of a gain providing method, comprising: an optical rotator for propagating a signal light having uneven power for each optical channel only in a predetermined direction; A splitter / multiplier that separates the power of the signal light passing through the optical rotator for each optical channel and sums up the signal channels incident to it in the opposite direction; A plurality of optical paths arranged to pass optical powers to be separated or combined by the splitter / multiplier; Including an optical waveguide made of a rare earth element doped silica-based material and an upper pump light source for irradiating light from the vertical upper portion of each of the optical waveguides, provided at the end of each optical path to give different gains for each channel An optical waveguide amplifier array for flattening power of each channel of the signal light; And a reflector installed at an end of each unit of the optical amplifier array to reflect the amplified light. Characterized in having a.

At least one of the splitter, the combiner, and the optical waveguide amplifier array may be made in a PLC form.

The optical power flattener according to the two aspects, the power measuring device for measuring the power flattened by the optical waveguide amplifier array for each channel; And a controller for adjusting amplification intensity of each channel of the optical waveguide amplifier array when the planarization result of the power measurement of the power meter does not meet a predetermined criterion.

Prior to describing an embodiment of the present invention, an optical waveguide amplifier to which an upper pumping method, which is important for the present invention, is applied is shown in FIG. 1 to explain its operation.

Referring to FIG. 1, a lower cladding layer 110 made of silica is formed on a substrate 100, and a core layer made of a silica-based material co-doped with nanocrystals and rare earth elements is formed as the waveguide 120. Formed. The upper cladding layer 130 made of silica is formed on the waveguide 120 again. A broadband light source (not shown) is installed on the top of the waveguide 120 to split the pumping light into the waveguide 120 from above. The light entering the waveguide 120 causes electrobonding of the nanocrystals, whereby rare earth elements are excited. The input light receives energy from the excited rare earth elements and passes through the waveguide 120 to be amplified and output to the output light.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

2 is a schematic configuration diagram of an optical power flattener according to a first embodiment of the present invention.

Referring to FIG. 2, signal light having uneven power for each optical channel is input to the demultiplexer 200 formed of a planar grating through the input terminal I. The input signal light is mainly multi-wavelength light transmitted through an optical communication system or amplified by an optical amplifier having an uneven gain curve. Optical signals having different wavelengths are separated for each optical channel by diffraction in the demultiplexer 200 serving as an optical splitter which is a planar lattice, and the separated optical power enters the waveguides 210 corresponding to the plurality of optical paths. . On the other hand, the opposite action occurs in the multiplexer 202, which is a planar grating, acts as an optical combiner. A portion of the waveguide 210 has a structure as described in the description of FIG. 1, and a pump light source 212 is positioned at the top of each waveguide so as to enable pumping. Therefore, this part consists of the structure of the upper pumping optical waveguide amplifier. Each pump light source 212 may be supplied with different power 230 by the controller 250 to vary the degree of light amplification for each waveguide 210. Therefore, if the separated optical power is different for each of the waveguides 210, the optical power flattener may provide a flattened gain by amplifying the light having the weak optical power strongly and weakly amplifying the light having the strong optical power. The planar channel-specific optical power as described above is combined in the multiplexer 202 and exits through the output terminal (O). On the other hand, in the present embodiment, the portion 220 of the signal light exiting through the output terminal (O) is extracted by the coupler 222 and sent to the Optical Spectrum Analyzer (OSA) 240, which serves as a power meter to transmit the optical power for each channel After the measurement, this information is sent to the controller 250. When the controller 250 determines that the flatness of the output optical signal does not reach a desired level, the controller 230 adjusts the power 230 supplied to the pump light source 212 for each channel so as to flatten it. Thus, dynamic optical power planarization can be achieved. The demultiplexer 200, the multiplexer 202, and the waveguides 210 used in this embodiment are preferably made in the form of a PLC (Planar Lightwave Circuit) to facilitate integration.

In the present embodiment, a method of extracting a part of the signal light which is combined by the multiplexer 202 and then exits through the output terminal O in measuring the optical power for each channel is used by the coupler 222. After optical amplification is completed, a method of extracting light amplified directly from the waveguide 210 may be used.

3 is a schematic configuration diagram of an optical power flattener according to a second embodiment of the present invention.

The structure shown in FIG. 3 applies the fact that the demultiplexer 200 and the multiplexer 202 have a symmetrical structure in FIG. 2. Accordingly, in FIG. 3, the optical splitter / multiplexer 300 is used as one device having both the functions of the demultiplexer and the multiplexer. Also in this embodiment, signal light having uneven power for each optical channel is input through the input terminal I. The input signal light is mainly multi-wavelength light transmitted through an optical communication system or amplified by an optical amplifier having an uneven gain curve. The input signal light enters the optical splitter / multiplexer 300 through the optical rotator 310 for advancing it only in one predetermined direction. The optical splitter / multiplier 300 serves as the optical splitter when the light passes in its direction in the optical rotator 310 and vice versa. Therefore, light entering the optical splitter / multiplexer 300 through the optical rotator 310 is separated for each optical channel, and the separated optical power enters the waveguides 320 corresponding to the plurality of optical paths. An end portion of the waveguide 320 has a structure as described in the description of FIG. 1, and a pump light source 330 is positioned at each upper portion of each waveguide to enable pumping. Therefore, this part consists of the structure of the upper pumping optical waveguide amplifier array. Each pump light source 330 may be supplied with different power 360 by the controller 350 to vary the degree of light amplification for each of the waveguides 320. Therefore, if the separated optical power is different for each of the waveguides 320, the optical power flattener may provide a gain by amplifying the light having the weak optical power strongly and weakly amplifying the light having the strong optical power. In addition, while placing the pump light source 330 to the end of the waveguide 320, a reflecting mirror 340 is installed therein so that the first amplified optical powers are amplified again by returning by the reflection. The optical powers returned to the optical splitter / multiplexer 300 through two amplifications are thus combined by the optical splitter / multiplexer 300 and then proceed to the output terminal O. FIG. On the other hand, a part of the signal light exiting through the output terminal (O) is extracted by the coupler 322 and sent to the OSA 380 acting as a power meter to measure the optical power for each channel and sends this information to the controller 350. . When the controller 350 determines that the flatness of the output optical signal does not reach the desired level, the power 360 supplied to the pump light source 330 for each channel is adjusted to flatten it. Thus, dynamic optical power planarization can be achieved. The optical splitter / multiplexer 300 and the waveguides 320 used in this embodiment are preferably made in the form of a Planar Lightwave Circuit (PLC).

As described above, the embodiments of the present invention have been described, but the present invention is not limited, and it is apparent that many modifications are possible by those skilled in the art within the technical idea of the present invention.

Therefore, in the exemplary embodiment of the present invention, only the gain-providing optical power planarizer has been described. However, since the attenuation occurs due to the absorption of light according to the length of the optical waveguide, the optical waveguide does not operate the pump light. If it is configured differently according to the optical power flattener of the present invention can be used as a loss method rather than a gain method. That is, the optical power flattener of the present invention can be used in the same manner as in the prior art.

As described above, according to the present invention, the output of the optical channel can be smoothed and controlled as desired without deteriorating the signal-to-noise ratio.

Claims (11)

In the optical power flattener for flattening the power of the signal light output for each optical channel is not flat, A splitter for separating signal light having uneven power for each optical channel for each optical channel; A plurality of optical paths configured to pass signal light separated for each optical channel by the splitter; An optical waveguide made of a silica-based material doped with a rare earth element and an upper pump light source for irradiating light from each of the vertical upper portions of the optical waveguide, and provided in each of the optical paths to give different gains for each channel, thereby providing the channel of the signal light. An optical waveguide amplifier array for flattening star power; And An optical combiner for adding signal signals for each optical channel flattened by the optical amplifier array; Gain-providing optical power planarizer, characterized in that it comprises a. delete delete delete delete The gain providing optical power flattener of claim 1, wherein at least one of the splitter, the combiner, and the optical waveguide amplifier array is in the form of a PLC. The apparatus of claim 1, further comprising: a power meter for measuring power flattened by the optical waveguide amplifier array for each channel; And a controller for adjusting amplification intensity of each channel of the optical waveguide amplifier array when the planarization result of the power measurement of the power meter does not meet a predetermined criterion. Gain-providing optical power flattener characterized in that it further comprises. An optical rotator for advancing a signal light having an uneven power for each optical channel only in a predetermined direction; A splitter / divider that separates the power of the signal light that has passed through the optical rotator for each optical channel and adds all the signal channels incident to it in the opposite direction; A plurality of optical paths arranged to pass optical powers to be separated or combined by the splitter / multiplier; Including an optical waveguide made of a rare earth element doped silica-based material and an upper pump light source for irradiating light from the vertical upper portion of each of the optical waveguides, provided at the end of each optical path to give different gains for each channel An optical waveguide amplifier array for flattening power of each channel of the signal light; And A reflector installed at each end of the optical waveguide amplifier array to reflect the amplified light; Gain-providing optical power planarizer, characterized in that it comprises a. delete 10. The gain providing optical power flattener of claim 8, wherein at least one of the splitter, the combiner, and the optical waveguide amplifier array is in the form of a PLC. 9. The apparatus of claim 8, further comprising: a power meter for measuring power flattened by the optical waveguide amplifier array for each channel; And a controller for adjusting amplification intensity of each channel of the optical waveguide amplifier array when the planarization result of the power measurement of the power meter does not meet a predetermined standard. Gain-providing optical power flattener characterized in that it further comprises.